Changes in tags are saved to the data store.
Also, when a task is created, its arbit tags are stored. Issue 696 fixed.
from django.contrib.gis.geos import GEOSGeometry, LinearRing, Polygon, Point
from django.contrib.gis.maps.google.gmap import GoogleMapException
from math import pi, sin, cos, log, exp, atan
# Constants used for degree to radian conversion, and vice-versa.
DTOR = pi / 180.
RTOD = 180. / pi
class GoogleZoom(object):
"""
GoogleZoom is a utility for performing operations related to the zoom
levels on Google Maps.
This class is inspired by the OpenStreetMap Mapnik tile generation routine
`generate_tiles.py`, and the article "How Big Is the World" (Hack #16) in
"Google Maps Hacks" by Rich Gibson and Schuyler Erle.
`generate_tiles.py` may be found at:
http://trac.openstreetmap.org/browser/applications/rendering/mapnik/generate_tiles.py
"Google Maps Hacks" may be found at http://safari.oreilly.com/0596101619
"""
def __init__(self, num_zoom=19, tilesize=256):
"Initializes the Google Zoom object."
# Google's tilesize is 256x256, square tiles are assumed.
self._tilesize = tilesize
# The number of zoom levels
self._nzoom = num_zoom
# Initializing arrays to hold the parameters for each one of the
# zoom levels.
self._degpp = [] # Degrees per pixel
self._radpp = [] # Radians per pixel
self._npix = [] # 1/2 the number of pixels for a tile at the given zoom level
# Incrementing through the zoom levels and populating the parameter arrays.
z = tilesize # The number of pixels per zoom level.
for i in xrange(num_zoom):
# Getting the degrees and radians per pixel, and the 1/2 the number of
# for every zoom level.
self._degpp.append(z / 360.) # degrees per pixel
self._radpp.append(z / (2 * pi)) # radians per pixl
self._npix.append(z / 2) # number of pixels to center of tile
# Multiplying `z` by 2 for the next iteration.
z *= 2
def __len__(self):
"Returns the number of zoom levels."
return self._nzoom
def get_lon_lat(self, lonlat):
"Unpacks longitude, latitude from GEOS Points and 2-tuples."
if isinstance(lonlat, Point):
lon, lat = lonlat.coords
else:
lon, lat = lonlat
return lon, lat
def lonlat_to_pixel(self, lonlat, zoom):
"Converts a longitude, latitude coordinate pair for the given zoom level."
# Setting up, unpacking the longitude, latitude values and getting the
# number of pixels for the given zoom level.
lon, lat = self.get_lon_lat(lonlat)
npix = self._npix[zoom]
# Calculating the pixel x coordinate by multiplying the longitude value
# with with the number of degrees/pixel at the given zoom level.
px_x = round(npix + (lon * self._degpp[zoom]))
# Creating the factor, and ensuring that 1 or -1 is not passed in as the
# base to the logarithm. Here's why:
# if fac = -1, we'll get log(0) which is undefined;
# if fac = 1, our logarithm base will be divided by 0, also undefined.
fac = min(max(sin(DTOR * lat), -0.9999), 0.9999)
# Calculating the pixel y coordinate.
px_y = round(npix + (0.5 * log((1 + fac)/(1 - fac)) * (-1.0 * self._radpp[zoom])))
# Returning the pixel x, y to the caller of the function.
return (px_x, px_y)
def pixel_to_lonlat(self, px, zoom):
"Converts a pixel to a longitude, latitude pair at the given zoom level."
if len(px) != 2:
raise TypeError('Pixel should be a sequence of two elements.')
# Getting the number of pixels for the given zoom level.
npix = self._npix[zoom]
# Calculating the longitude value, using the degrees per pixel.
lon = (px[0] - npix) / self._degpp[zoom]
# Calculating the latitude value.
lat = RTOD * ( 2 * atan(exp((px[1] - npix)/ (-1.0 * self._radpp[zoom]))) - 0.5 * pi)
# Returning the longitude, latitude coordinate pair.
return (lon, lat)
def tile(self, lonlat, zoom):
"""
Returns a Polygon corresponding to the region represented by a fictional
Google Tile for the given longitude/latitude pair and zoom level. This
tile is used to determine the size of a tile at the given point.
"""
# The given lonlat is the center of the tile.
delta = self._tilesize / 2
# Getting the pixel coordinates corresponding to the
# the longitude/latitude.
px = self.lonlat_to_pixel(lonlat, zoom)
# Getting the lower-left and upper-right lat/lon coordinates
# for the bounding box of the tile.
ll = self.pixel_to_lonlat((px[0]-delta, px[1]-delta), zoom)
ur = self.pixel_to_lonlat((px[0]+delta, px[1]+delta), zoom)
# Constructing the Polygon, representing the tile and returning.
return Polygon(LinearRing(ll, (ll[0], ur[1]), ur, (ur[0], ll[1]), ll), srid=4326)
def get_zoom(self, geom):
"Returns the optimal Zoom level for the given geometry."
# Checking the input type.
if not isinstance(geom, GEOSGeometry) or geom.srid != 4326:
raise TypeError('get_zoom() expects a GEOS Geometry with an SRID of 4326.')
# Getting the envelope for the geometry, and its associated width, height
# and centroid.
env = geom.envelope
env_w, env_h = self.get_width_height(env.extent)
center = env.centroid
for z in xrange(self._nzoom):
# Getting the tile at the zoom level.
tile_w, tile_h = self.get_width_height(self.tile(center, z).extent)
# When we span more than one tile, this is an approximately good
# zoom level.
if (env_w > tile_w) or (env_h > tile_h):
if z == 0:
raise GoogleMapException('Geometry width and height should not exceed that of the Earth.')
return z-1
# Otherwise, we've zoomed in to the max.
return self._nzoom-1
def get_width_height(self, extent):
"""
Returns the width and height for the given extent.
"""
# Getting the lower-left, upper-left, and upper-right
# coordinates from the extent.
ll = Point(extent[:2])
ul = Point(extent[0], extent[3])
ur = Point(extent[2:])
# Calculating the width and height.
height = ll.distance(ul)
width = ul.distance(ur)
return width, height